RU2193485C1 - Solid material cutting apparatus - Google Patents

Abstract

FIELD: solid material processing equipment. SUBSTANCE: apparatus for cutting solid materials, in particular, stone, has saw body with opening and stopper for placing and withdrawal of rolling bodies, drive ring provided with cutting members and movably fixed on saw body through movable rolling bodies, and tightening drive mechanism composed of single pair of conical drive rollers. Pair of drive rollers is positioned on apparatus casing so that rollers press drive ring and shift it relative to saw casing to provide for kinematic coupling with drive. EFFECT: increased efficiency by providing cutting at high speeds and increased service life of saw cutting members. 9 cl, 4 dwg

Description

 The invention relates to devices for processing various solid materials by cutting using a circular saw, for example stone processing, and more particularly to processing stone using a circular saw.

 Currently, circular saws are widely used to process various hard materials by cutting. However, their application for relatively deep cutting is not effective, since the diameter of the saw blade should be approximately three times the cutting depth, and the overall dimensions of the cutting tool are excessively large, which leads to an increase in the dimensions of the machine itself, an increase in the price of the tool, machine tool and manufactured products .

 For the implementation of deep cutting in solid materials, at moderate speeds of the process, it is known to use cutting tools in the form of circular saws.

 Known, for example, is a circular saw containing a drive ring with cutting elements mounted on a fixed bearing on a bearing (SU 273702; MKI B 28 D 1/12; Bulletin "Discoveries, Inventions" 20, 1970) or movably fixed between two fixed cheeks (SU 605971; MKI B 28 D 1/12; Bulletin "Discoveries, Inventions" 17, 1978), and drive.

 The disadvantages of these saws are the relatively large thickness of the drive ring with cutting elements, due to the need to ensure sufficient rigidity of the proposed design of the tool, high load guide rails of the drive ring and a relatively low cutting speed. The large thickness of the cutting tool leads to an increase in the width of the cut, which, in turn, requires an increase in cutting forces and is the reason for the increase in the specific energy consumed necessary for the cutting process and the consumption of relatively expensive cutting elements. In addition, the consumption of the processed material increases. It should also be noted that a high workload of the guide apparatus reduces the service life of the saw, and a low cutting speed limits the possibility of using modern cutting elements, such as diamond briquettes, which work efficiently at high cutting speeds. With an increase in the depth of cut and when making an inclined cut, especially at negative tilt angles of the cutting tool, the supply of coolant to the cutting zone is significantly complicated, which leads to excessive consumption of coolant (water), and also negatively affects the durability of the cutting elements.

 Part of the above disadvantages is eliminated in our proposed design of a circular saw (Patent RU 2146612; 06/25/1999).

 However, as our tests showed, the proposed design of the circular saw provides normal operation at relatively low speeds (up to 10 m / s) and limited drive power (up to 15 kW). To ensure the transfer of more power to the drive ring, the force necessary for transmitting movement acting on the drive ring from the side of the protracted drive mechanism has to be increased so much that it creates a radially non-uniform deformed state of the drive ring around its perimeter. This worsens the rolling conditions of the rolling bodies, which is the reason for the reduction in the efficiency of the circular saw and limits the value of the cutting speed. In addition, for the normal operation of the circular saw, it is necessary to ensure the installation of the maximum number of rolling elements without significantly increasing the gap between the circumference of the envelope of the rolling element and the inner circumference of the drive ring. It is also necessary to ensure a sufficiently accurate installation on the machine of a long drive mechanism relative to the drive ring and the saw body to ensure both the rotation of the drive ring in its middle plane and the uniform distribution of contact pressure and transmitting torque between the leading tapered rollers.

 The basis of the present invention is the creation of a device with a circular saw for cutting solid materials with such a design that would allow the cutting process at high speeds, ensuring the durability of the cutting elements of the saw.

 This problem was solved by creating a device for cutting solid materials, mainly stone, including a saw body equipped with a segment recess, a peripheral raceway and an opening with a plug, a drive ring equipped with cutting elements and an internal raceway, movably fixed to the saw body by means of movably mounted rolling bodies , a protracted drive mechanism consisting of at least one pair of drive tapered rollers, a drive and a device body, characterized in that the saw body and the protracted the drive mechanism is mounted on the device body in such a way that a pair of leading tapered rollers mounted in a segment recess of the saw body symmetrically relative to its mid-plane, shifting, creates the necessary contact pressure on the ring chamfers available on the lateral planes of the drive ring, providing a kinematic connection of the drive ring with the drive of the device, and the rolling elements are installed in the raceways of the saw body and the drive ring using an opening located on the periphery of the saw body in the zone of positive radial displacement of the drive ring and equipped with a removable plug equipped with a segment groove that identically complements the raceway of the saw body.

 The saw body is equipped with a peripheral annular raceway designed to guide the movement of the rolling elements and the perception of their contact pressure arising both from the action of the protracted drive mechanism and from the cutting forces that occur during operation of the device. The opening with a plug allows you to set the maximum number of rolling elements in the intermediate zone formed between the raceways of the saw body and the drive ring. The segment groove on the surface of the plug prevents shock loads on the rolling elements when starting up the device, when the speed of movement of the rolling elements is low. At high rotational speeds, the displacement of the drive ring relative to the saw body in the area of the opening creates a guaranteed gap between the rolling bodies and the plug, which eliminates the possibility of shock loads. The opening also allows you to remove the rolling elements from the raceways and easily remove the drive ring. The saw body is fixed to the device body in such a way that in the segmented recess of the saw body the leading conical rollers of the protracted drive mechanism are arranged in pairs symmetrically with respect to the middle plane of the raceway and protrude beyond the outer circumference of the saw body with their periphery. The drive ring has an internal raceway, and the side faces at the intersection with the inner cylindrical surface are provided with annular chamfers along which it contacts the driving conical rollers. The width of the drive ring is determined on the basis of the minimum diameter of the rolling elements, satisfying the condition of contact strength under the action of a working load on them, and the width of the ring chamfers necessary for transmitting contact pressure by the conical rollers. The minimum thickness of the drive ring is determined from the condition of the strength of the ring from the action of the working load on it, and the maximum thickness is determined from the condition of flexibility that provides the necessary contact of the raceway with the rolling bodies on the working part of the saw body. Cutting elements are fixed on the outer cylindrical surface of the drive ring. The outer diameter of the annular raceway of the drive ring slightly exceeds the diameter of the circumference of the envelope of the rolling body, which avoids the pressure of the rolling bodies on the saw body in the installation area of the opening. The magnitude of the difference between these diameters is limited by the condition of ensuring permissible contact pressure on the rolling elements from the side of the drive ring. The segment recess on the saw body is diametrically opposed to the cutting zone. The long drive mechanism is installed in the segmented recess of the saw body symmetrically with respect to its median plane. Leading conical rollers of the protracted drive mechanism are provided with the possibility of radial movement and, pressing on the annular chamfers made at the intersection of the lateral planes of the drive ring with the inner surface, inform it in the contact zone of the radial displacement relative to the saw body, thereby providing the necessary contact pressure for transmitting the drive ring movement appropriate power. The pressure force acting on the drive ring from the side of the drive rollers deforms it, providing full contact of the rolling bodies with the drive ring on the part of the saw that is in direct contact with the material being processed. Leading conical rollers are kinematically connected with the drive of the device and can be moved both with the main drive engine, and when using a cardan gear, regardless of the engine.

 To ensure cooling of the cutting elements, the drive ring and rolling elements, the saw body can be equipped with internal grooves, through which a cooling mixture, for example water, is supplied directly to the cutting zone. At the same time, the saw body is equipped with side sheets, between which grooves are made, coming from the nozzle mounted on the device body and fixed with the saw body to supply the mixture to the cutting zone. The feed pressure of the mixture should ensure the presence of the mixture in the raceway above the cutting depth, which will eliminate the possibility of cutting waste entering the raceway.

 The drive ring and the saw body can be equipped with several peripheral raceways, which will significantly increase the stiffness and stability of the drive ring relative to its middle plane, which will allow the operation of the saw in more severe conditions.

 The drive ring in cross section may have a T-shape, the wide part of which is adjacent to the inner surface of the ring and provided with an inner annular raceway. On the outer thickened part of the drive ring there are annular chamfers along which thrust rollers are installed, which allow to reduce the bending moment acting on it, significantly reduce the ring deformation and increase the transmitted power.

 Pairs of driving conical and thrust rollers can be equipped with damping devices. This will reduce the dynamic vibrations that occur during the cutting process, and increase the durability of the details of the hole saw.

To ensure good adhesion between the drive ring and the conical drive rollers, the conical surface of these rollers can be coated with a friction coating, for example, FMK-8 (45% Fe; 25% Ni; 10% Cr; 6% W; 7% Cu ₂ S and 7% graphite).

 It is convenient to use rolling elements of two different diameters to increase the efficiency of the hole saw, reduce the wear of the rolling elements and improve the water supply to the cutting zone. Moreover, they need to be installed in the raceway sequentially: between the rolling bodies of one diameter, a rolling body of a different diameter is set.

 To facilitate the installation of the saw in a lingering drive mechanism and to ensure the minimum thickness of the drive ring, the thickness of the annular part of the segmented recess of the saw body should be reduced. Since virtually no significant load actually acts on this part of the saw body, it can be designed as a plug-in.

 You can equip the protracted drive mechanism with a mechanism for displacing the drive ring relative to the saw body in the plane of rotation at an angle to the direction of its radius. This will allow you to rotate the zone of complete contact of the rolling elements with the raceways relative to the geometric center of the saw body and thereby produce the cutting process in different parts of the periphery of the saw.

 To ensure the safe operation of the device, a safety cover should be provided, which can protect service personnel from possible damage to rotating parts.

 The low specific load on the guide device of the circular saw allows the use of rolling elements made of materials with relatively low contact strength or on their surface and on the surface of the ring tracks to create a layer of anticorrosive material, such as non-ferrous metals or plastics, which will allow the operation of the proposed saw without lubrication in a liquid environment, and the ability to restore anti-corrosion coating will significantly extend the life of the saw. The small thickness of the drive ring gives it the necessary flexibility and allows using the vertical displacement of the saw body relative to the protracted drive mechanism to install or dismantle the drive ring, as well as create the necessary contact force to transmit the corresponding power using conical rollers.

For a better understanding of the invention, the following are specific options for its implementation with reference to the accompanying drawings, in which:
figure 1 schematically shows a device with a hole saw, General view;
figure 2 is a section aa of figure 1;
figure 3 is a section bb In figure 1;
figure 4 - cutout I figure 1.

 The proposed circular saw consists of a movable drive ring 2 mounted on the rolling elements 3, movably mounted on the raceway 14 of the saw body 1. The raceway 3 is installed in the raceway 14 using the opening 15, which is closed by a plug 16 (figure 4). The saw body 1 is fixed to the device body 8 with the help of tightening bolts 11 and the bar 7. At the same time, in the segmented recess 17 of the saw body is installed a long-lasting drive mechanism consisting of one pair of leading tapered rollers 13. The saw can be equipped with one pair of thrust rollers 12 (Fig. .3). Coolant is supplied to the cutting zone through the nozzle 9 and the internal grooves 4, which are located between the side sheets 6 and the saw body 1.

 The saw works as follows. By moving the protracted drive mechanism relative to the saw body, the drive ring is tightened. After reaching the necessary contact pressure between the tapered rollers and the drive ring, a rotational movement is reported to the drive ring by means of a device drive. The feed for cutting is carried out by moving the housing of the cutting device relative to the stone block.

 The present invention can be used in the processing of various solid materials by cutting, for example, in stone processing.

Claims (9)

 1. A device for cutting solid materials, mainly stone, comprising a saw body having a peripheral raceway, a drive ring provided with cutting elements and an inner raceway, movably fixed to the saw body by means of movably mounted rolling elements, a drawback drive mechanism, consisting of at least from one pair of leading tapered rollers, a drive and a device body, characterized in that the saw body is made with a segment recess in which a long drive mechanism is installed such In a nutshell, a pair of leading tapered rollers mounted in a segmented recess of the saw body symmetrically with respect to its median plane creates the necessary contact pressure on the annular chamfers on the lateral planes of the drive ring to provide kinematic coupling of the drive ring to the drive of the device, and the rolling bodies are raceways of the saw body and the drive ring through the opening on the periphery of the saw body, equipped with a removable plug with a segment groove that identically complements the raceway I saw the body.  2. The device according to claim 1, characterized in that the saw body has internal grooves for supplying cooling mixtures, for example, water to the cutting zone.  3. The device according to claim 1 or 2, characterized in that the saw body and the drive ring are equipped with more than one peripheral raceways.  4. The device according to any one of paragraphs. 1-3, characterized in that the drive ring in cross section is T-shaped and the device is equipped with at least one pair of thrust rollers.  5. The device according to any one of paragraphs. 1-4, characterized in that the persistent and driving tapered rollers are equipped with damping devices.  6. The device according to any one of paragraphs. 1-5, characterized in that the friction coating is applied to the conical surfaces of the drive rollers.  7. The device according to any one of paragraphs. 1-6, characterized in that the dimensions of the rolling bodies through one have the same size.  8. The device according to any one of paragraphs. 1-7, characterized in that the leading tapered rollers have the ability to change the direction of contact pressure.  9. The device according to any one of paragraphs. 1-8, characterized in that the annular part of the segmented recess of the saw body is removable.

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